Targeting Tumor Cells Overexpressing the Human Epidermal Growth Factor Receptor 3 with Potent Drug Conjugates Based on Affibody Molecules

Recent advances of affibody molecules in biomedical applications

Affibody molecules are 58-amino-acid peptides with a molecular weight of about 6.5 kDa, derived from the Z domain of Staphylococcal Protein A. Since they have been used as substitutes for antibodies in biomedicine, several therapeutic affibody molecules have been developed for clinical use. Additionally, affibody molecules have been designed for a range of different applications. This review focuses on the progress made in the last five years in the field of affibody molecules and their potential uses in medical imaging, especially in oncology and cancer treatment. It covers areas such as molecular imaging, targeted delivery of toxic drugs, and their use in combination with nanoparticles. We also highlight some current biomedical applications where affibody molecules are commonly used as a "guide." Due to their many advantages, affibody molecules offer significant potential for applications in both biochemical and medical fields.

Affibody-Drug Conjugates Targeting the Human Epidermal Growth Factor Receptor-3 Demonstrate Therapeutic Efficacy in Mice Bearing Low Expressing Xenografts

The outcome of clinical trials evaluating drugs targeting the human epidermal growth factor receptor 3 (HER3) has been poor, with primary concerns related to lack of efficacy. HER3 is considered a difficult target since its overexpression on tumors is relatively low and there is normal expression in many different organs. However, a significant number of patients across different cancer indications have overexpression of HER3 and the development of novel modalities targeting HER3 is therefore warranted. Here, we have investigated the properties of affibody-based drug conjugates targeting HER3. The HER3-targeting affibody molecule ZHER3 was fused in a mono- and bivalent format to an engineered albumin-binding domain (ABD) for in vivo half-life extension and was coupled to the cytotoxic drug DM1 via a non-cleavable maleimidocaproyl (mc) linker. In vivo, a moderate uptake was observed for [99mTc]Tc-labeled ZHER3-ABD-ZHER3-mcDM1 in HER3 expressing BxPC3 tumors (3.5 ± 0.3%IA/g) at 24 h after injection, and clearance was predominately renal-mediated. Treatment of mice with BxPC3 human pancreatic cancer xenografts showed that a combination of ZHER3-ABD-ZHER3-mcDM1 and its cytostatic analog ZHER3-ABD-ZHER3 was efficacious and superior to treatment with only ZHER3-ABD-ZHER3, providing tumor growth inhibition and longer median survival (90 d) in comparison to monotherapy (68 d) and vehicle control (49 d). ZHER3-ABD-ZHER3-mcDM1 was found to be a potent drug conjugate for the treatment of HER3-expressing tumors in mice.

Surface-engineered bacteria in drug development

Bacterial surface display in combination with fluorescence-activated cell sorting is a versatile and robust system and an interesting alternative approach to phage display for the generation of therapeutic affinity proteins. The system enables real-time monitoring and sorting of cell populations, which presents unique possibilities for drug development. It has been used to develop several affibody molecules currently being evaluated preclinically for the treatment and diagnosis of, for example, cancer and neurodegenerative diseases. Additionally, it can be implemented in other areas of drug design, such as for mapping epitopes and evolving enzyme specificities.

Non-Immunoglobulin Synthetic Binding Proteins for Oncology

Extensive application of technologies like phage display in screening peptide and protein combinatorial libraries has not only facilitated creation of new recombinant antibodies but has also significantly enriched repertoire of the protein binders that have polypeptide scaffolds without homology to immunoglobulins. These innovative synthetic binding protein (SBP) platforms have grown in number and now encompass monobodies/adnectins, DARPins, lipocalins/anticalins, and a variety of miniproteins such as affibodies and knottins, among others. They serve as versatile modules for developing complex affinity tools that hold promise in both diagnostic and therapeutic settings. An optimal scaffold typically has low molecular weight, minimal immunogenicity, and demonstrates resistance against various challenging conditions, including proteolysis - making it potentially suitable for peroral administration. Retaining functionality under reducing intracellular milieu is also advantageous. However, paramount to its functionality is the scaffold's ability to tolerate mutations across numerous positions, allowing for the formation of a sufficiently large target binding region. This is achieved through the library construction, screening, and subsequent expression in an appropriate system. Scaffolds that exhibit high thermodynamic stability are especially coveted by the developers of new SBPs. These are steadily making their way into clinical settings, notably as antagonists of oncoproteins in signaling pathways. This review surveys the diverse landscape of SBPs, placing particular emphasis on the inhibitors targeting the oncoprotein KRAS, and highlights groundbreaking opportunities for SBPs in oncology.